FR2572200A1 - DIFFRACTION APPARATUS USING TWO CONCRETE MIRRORS AND CORRECTED HOLOGRAPHIC PLANE NETWORK, AND NETWORK RECORDING METHOD - Google Patents

Abstract

PROCESS FOR MAKING A CORRECTED HOLOGRAPHIC NETWORK FOR USE IN AN APPARATUS IN WHICH THE ENTRY LIGHT IS COLLIMATED BY A SPHERICAL MIRROR 2 TOWARDS A NETWORK 4 WHICH REFERS PARALLEL BEAMS TOWARDS ANOTHER FOCUSING SPHERICAL MIRROR 7. AN AUXILIARY HOLOGRAPHIC NETWORK 25 IS FIRST CREATED BY INTERFERENCE ON A SPHERICAL SURFACE 15 OF A PARALLEL BEAM SHAPED BY THE MIRROR 7 AFTER REFLECTION ON A PLANE MIRROR 12 AND FROM A DIVERGENT BEAM FROM THE CENTER OF SURFACE 15. WE RECORD THEN THE NETWORK CORRECTS BY INTERFERENCE ON A FLAT SURFACE 22 OF A PARALLEL BEAM SHAPED BY MIRROR 2 AND ANOTHER PARALLEL BEAM SHAPED BY AUXILIARY NETWORK 25 ILLUMINATED FROM THE CENTER OF ITS SPHERICAL SURFACE.

Description

2572Z00

  The present invention relates to a diffraction apparatus, such as diffraction apparatus using two concave mirrors and a corrected holographic plane array, and

  a spectrograph or a monochromator, of the type using two mirrors concen-

  spheres and a planar network with improved quality of

  aberrations. It also relates to a method of hologram recording

  Plan network graph used in the device.

  Such devices are known, used for example in spectroscopy.

  Raman, and in which the light to be analyzed is introduced by an inlet slit disposed at an off-axis focus of a spherical mirror forming

  collimator, which sends a parallel beam back to a plane network of

  fraction. By diffraction the grating reflects the light in several ways.

  Parallel beams towards a second concave spherical focusing mirror.

  Thus, for each wavelength of the input light,

  separate images of the entrance slit; we can then either, for a func-

  spectrograph, record or observe the entire spectrum formed or, for monochromator operation, isolate a single

  wavelength through an exit slot.

  In such an apparatus the spherical collimation and focusing mirrors are used off axis and give rise to aberrations, in particular spherical aberrations to which can be added

  aberrations of coma and astigmatism.

  The present invention aims to reduce as much as possible these aberrations

  tions by correcting them by a particular line of the plane network, which may then have very slight variations of parallelism or pitch. This corrected network will be a holographic network, and the invention is also directed to the method used for the holographic recording of this planar network.

  According to the invention, the method of holographic recording of the

  Plan-corrected bucket has the following two successive phases:

  A - Realization of an auxiliary spherical network by recording

  holographically, on a concave spherical surface, fringes of inter-

  two monochromatic beams of the same wavelength

  taken in the correction band, - a parallel beam formed by one of the spherical mirrors of the apparatus

  from a source located at the associated home of use, and after

  bending on a plane mirror arranged in place of the network,? 7200

  - a divergent beam from another source in the center of the

spherical face.

  B - Realization of the final plan network by holographic recording

  on a flat surface arranged at the normal network location in the apparatus, interference fringes of two monochromatic beams of the same wavelength λ as in the previous phase,

  a parallel beam formed by the other of the spherical mirrors of the

  from a source located at the associated

  a parallel beam formed by reflection on the auxiliary network at

  shot from another source located at the center of the spherical surface support network.

  The invention will be better understood by referring to a mode of realization

  particular example given and represented by the

the accompanying.

  FIG. 1 is an optical diagram that applies equally well to

  prior state of the art that a device made according to the invention

  since the only difference is in the drawing of the lines of the plane network. -

  Figures 2A and 2B illustrate the two successive phases of the

  method according to the invention for recording the planar network.

  We find in Figure 1 the usual elements of a conventional diffraction apparatus used here in monochromator. The light to be analyzed

  introduced by the entrance slot 1, disposed at an off-axis focus of the

  Spherical beam 2 which thus returns a parallel beam 3 to a diffraction plane grating 4. The grating 4 reflects several parallel beams such as 5 and 6, each corresponding to different wavelengths, to a second spherical focusing mirror 7. For each wavelength of the light introduced at 1, different images 8 and 9 of the input slot are thus obtained and the wavelength chosen can be isolated.

by an exit slot 10.

  The diffraction apparatus produced according to the invention uses exactly

  the same optical scheme, but the particular layout of the lines of the

  plane bucket 4 corrects the aberrations introduced by the mirrors

spherical 2 and 7.

  The particular method of holographic recording of the plane array 4 comprises in a first phase the intermediate realization of a

  auxiliary concave holographic network, then in a second phase the

  plan network 4. It will be seen from Figures 2A and 2B that

  these two phases of the recording process, the two spherical mirrors

  2 and 7, as well as slots 1 and 10, are at the same relative positions

  only for use according to Figure 1.

  In the first phase (FIG. 2A), the planar array has been replaced by a plane mirror 12. Slot 10 is used as an entrance slot for a monochromatic light of wavelength λlo, preferably in the range of lengths of wave lights that will be used in the device. The spherical mirror 7 then reflects a parallel beam 13

  that the mirror 12 returns to another parallel beam 14.

  The path of the beam 14 has a spherical surface 15

  covered in the usual way for the recording of holographic networks.

  photosensitive resin. The spherical surface is simultaneously illuminated

  15 by a diverging beam 16 of monochromatic light of the same wavelength 10 as the beam 14, and coming from a slot 17 disposed at the center of the sphere 15. After printing on the coating of the surface 15

  interference fringes of the beams 14 and 16 are processed in the usual manner.

  bituelle the surface 15 to lead to the formation on this surface of a concave holographic grating whose features reproduce the intersection

  complex interference surfaces by the spherical surface 15.

  For the second phase of the operation (Figure 2B) the auxi-

  The concave link 25 obtained in the first phase is returned to the same place as the surface 15, and the plane mirror 12 is replaced by a flat surface 22 covered, still in the usual manner for recording holographic gratings, with a photosensitive resin. . The surface 22 is then illuminated by a first monochromatic parallel beam 23 of wavelength 10.

  from slot 1 after reflection on the mirror 2. Simultaneously the surface

  this is illuminated by a second monochromatic parallel beam 24,

  same wavelength lo0 from the slot 17 after reflection on the

  It is known that the network 25 having been registered by the

  terferences of a parallel beam 14 and a diverging beam 16 in

  of slot 17, it suffices to illuminate the network 25 by the single

  ceau from 17 so that it reflects on the network in a beam 24 of the same characteristic as the recording beam 14; that is to say, parallel and directed towards the surface 22 substituted for the mirror 12. 1 After printing on the coating of the surface 22 of the interference fringes of the beams 23 and 24 is treated in the usual way the

  surface 22 to result in the formation on this surface of a hologram

  graphic plane whose features reproduce the intersection by the plane 22

2572OO

4 -

  interference surfaces of the parallel beams 23 and 24. It is this

  flat bucket that will be used in 4 in the apparatus according to Figure 1.

  Overall, the interference surfaces of the plane waves of the

  parallel cords 23 and 24 are equidistant parallel planes and their

  tersection by the plane 22 leads to a plane network with parallel and equidistant lines. However the aberrations introduced by the spherical mirror

  2 result in plane flatness aberrations of the beam 23.

  Similarly, the flatness of the waves of the beam 14 (FIG 2A) has been aberrated.

  because of the mirror 7 and the same aberrations of flatness

  in beam 24 (FIG 2B) after reflection on the network 25 recorded

  from the beam 14. As a result, the overall parallel features

  of the network 4 actually have their own imperceptibility

  aberrations in their parallelism and the regularity of their step.

  It is observed that the aberrations thus intentionally created on the layout of the network 4 allow a very sensible correction of the aberrations.

  parasitically introduced by spherical mirrors 2 and 7.

  Example: A monochromator according to FIG.

  use of 4880 A, with 2 and 7 distance mirrors

  focal length respectively 639,699 and 639,226 mm with a plane network at 1200-

  lines per millimeter. The angle of the axis of the incident beam from the window

  te 1 with the axis at the top of the mirror 2 is 4,29421 degrees. Network 4

  the parallel beam 3 at an incidence of 8.130 degrees and returns the wavelength 4880 A at a reflection angle of 26.370 degrees. This reflected beam is at an angle of 4.82568 degrees with the normal at the top of the mirror 7. For the realization of the auxiliary network 25 a

  spherical surface 15 with a radius of 938 mm and a recording wavelength of

4880 t.

  Under these conditions, the quality of the image of the entrance slot is improved; in particular the astigmatism is reduced and the following performances are obtained, using input and output slots

  1 mm high and 0.005 mm wide.

2572200O

  Length Network no Corrected corrected waveband AI I Height 3131 1.4 0, 5 astigmatism 4880 1.4 0 I (mm) 5460 1.4 0.15 Resolution 3131 0.24 0.12

I (A) 4880 0.20 0.08

5460 0.20 0.08

Claims (2)

  1.- Method for producing a corrected plane holographic grating in a wavelength band for use in a device   diffraction pattern o light emitted by an input source (1) is collimated   a first spherical mirror (2) to the grating (4) which returns parallel beams to a second spherical focusing mirror (7) for forming a spectrum,   characterized by the fact that it comprises the following two successive phases your:   A - Realization of an auxiliary spherical network (25) by homogeneous recording   on a concave spherical surface (15), interfering fringes   two monochromatic beams of the same wavelength (lo) com-   taken in the correction band, - a parallel beam (14) formed by one (7) of the spherical mirrors of the apparatus from a source located at the associated use center   (10), and after reflection on a plane mirror (12) disposed in place of the   bucket (4), - a divergent beam (16) from another source located in the center (17) of the spherical surface (15), B - Realization of the final plane network (4) by holographic recording, on a flat surface (22) disposed at the normal network location (4)   in the apparatus, interference fringes of two monochromatic beams   of the same wavelength (lo) as in the previous phase, - a parallel beam (23) formed by the other (2) spherical mirrors of the apparatus from a source located at the home of use associated (1), - a parallel beam (24) formed by reflection on the auxiliary network   (25) from another source located at the center (17) of the spherical surface than network support (25).   2. Diffraction apparatus in which a light emitted by an input source (1) is collimated by a first spherical mirror (2) towards   a plane array (4) which returns parallel beams to a second half   spherical mirror (7) for forming a spectrum,   characterized in that the planar network (4) is a corrected network   using the method of claim 1.